DE2907673A1 - CIRCUIT FOR CONTROLLING A BISTABLE RELAY - Google Patents

Description

23Ό7673

SDS-Elektro GmbH "■ 79/2/1

Circuit arrangement for controlling a bistable relay (addendum to patent application P 27 47 6o7 «9-34)

The main application P 27 47 6o7 "9 ~ 34" refers to a Circuit arrangement for controlling a bistable relay, whose excitation coil is in series with a capacitor the series connection of coil and capacitor to excite the Realis and simultaneous charging of the capacitor is applied to excitation voltage and when there is no excitation voltage can be short-circuited by a semiconductor switch connected in parallel with its output circuit, whereby the Relay switches back to its original position.

The object on which the main application is based is to design a circuit arrangement of the type mentioned so that the automatic switching back of the bistable relay, which is desired when the excitation voltage is lost, with less effort can be implemented on components than in a known arrangement.

According to the main patent, the solution to this problem is achieved by that the semiconductor switch with its input circuit to a resistor element lying in series with the excitation coil and capacitor is connected in parallel and after the capacitor has been charged and the excitation voltage has been switched off a voltage drop occurring at the resistance element can be controlled in a conductive manner.

- 2 - §09881 / 0572

The present invention is based on the object of the circuit arrangements proposed in patent application P 27 47 6o7.9-34 to the effect that defined response and dropout voltages for the used with other circuit measures Relays and insensitivity to interference, e.g. in the form of voltage drops, can be implemented.

This object is achieved by the measures defined in the claims. On the one hand, there is an economic structure of the respective circuit arrangement can also be carried out with discrete components; on the other hand, circuit variants are indicated by the complex individual components that can only be implemented with great effort in an integration technology that may be considered be avoided.

The invention is explained in more detail below with reference to the exemplary embodiments shown in FIGS.

Fig. 5 shows a variant of an arrangement according to Fig. 3 or Fig. 2 of patent application P 27 47 6o7; 9, where instead of the Zener diode ZD1 the parallel connection of a resistor R 11 and a diode D 6 is used. This is particularly the case

a circuit structure with discrete components an economical Alternative. The reference voltage applied to the base of the transistor T 6 is derived from the series circuit of the Resistance R 5, the Zener diode ZD 2 and the diode D 7 won. The characteristic curve of the diode D 7 is shown in FIG. 6. As soon as the excitation voltage ü exceeds the reference voltage, the trigger stage T 5, T 6 is conductive and the relay RIs responds.

909881/0572

In the embodiment shown in Fig. 7, the resistor is R 1 and the Zener diode ZD 1 of FIG. 2 of patent application 27 47 6o7.9 by a trigger stage T 5, T 6 with a base voltage divider R 13, R 14 replaced. The flip-flop becomes conductive when the voltage drop caused by the excitation voltage U the threshold voltage of the base-emitter diode of the first flip-flop transistor T 6 exceeds. The relay RIs will excited and the capacitor C 1 charged. In Fig. 8, the additional transistor T 1o are conductive and at the same time the diode D 5 blocked.

If, however, the excitation voltage U is interrupted, the transistor T 1o blocks and the diode D 5 conducts, so that a low discharge current of the capacitor C 1 flows through the resistor R 2, causing a voltage drop sufficient to control the flip-flop T2, T3 . The capacitor C 1 can now discharge via the trigger stage T 2, T 3 and the RIs switches back to its starting position.

The trigger stages built up from the transistors T 2, T 3 and T 5, T 6 SCR 1, SCR 2 are identical and can also be replaced by others controllable semiconductors, e.g. thyristors, are replaced.

While in Fig. 2 of the patent application P 27 47 6o7.9 shown Arrangement, due to the junction capacitance of the Zener diode ZD 1, short voltage drops or fluctuations in the Excitation voltage U a discharge of the capacitor C 1, or a Switching back the relay RIs can trigger, this is in the The circuit according to FIG. 9 is avoided by the transistor T 4 connected upstream of the trigger stage T 2, T 3. The base electrode of the For this purpose, transistor T 4 is connected in series a resistor R 16 and a Zener diode ZD 3 with its cathode connected to the positive pole of the exciter voltage source. The zener tension the diode ZD 3 determines the voltage value until

to which the excitation voltage U can drop without a unintentional discharge of the capacitor C 1 and thus a switching back of the relay RIs is effected.

In the circuit arrangement shown in Fig. 1o is opposite that of Fig. 2 of the patent application P 27 47 6o7.9 in addition the ohmic resistance R 17 between the base electrode of the transistor T 2 and the collector electrode of the transistor T. inserted. This ensures that neither an excessively high current load nor a short circuit at the flip-flop stage T 2, T 3 can occur if the voltage rise at this trigger stage is too steep. Can just as well take the place of resistance R 17 is also an ohmic resistor between the collector electrode of the transistor T 2 and the base electrode of the transistor T 3 must be inserted.

FIG. 11 shows an embodiment in which, as in FIG Fig. 5 instead of the Zener diode ZD 1 (Fig. 2) of the patent application P 27 47 6o7.9 a parallel connection of a resistor R 11 and one polarized in the forward direction to the excitation voltage U. Diode D 6 is used. When the excitation voltage ü is switched off, the transistors are activated T 2, T 3 existing multivibrator due to the voltage drop across this parallel circuit D 6, R 11. Here, the capacitor C 1 discharged and the relay Rls switched back to its starting position.

In a further development of the embodiment according to FIG. 11 is according to 12 shows a further flip-flop, comprising the transistors T 5, T 6, connected upstream. This tilt stage corresponds in their Function of the multivibrator according to FIG. 3, however, differs in its structure from this one in that the reference voltage is obtained by the Zener diode ZD 4, which is between the base electrode of the first transistor T 6 and the emitter electrode of the second transistor T 5 is switched on.

- 5 909881/0672

13 and 14 explain the function of the circuit according to FIG. 12, 13 shows the characteristic of the Zener diode ZD 4 and FIG. 14 shows the switching behavior of the circuit arrangement with increasing and decreasing values Excitation voltage U illustrates. If, as shown in FIG. 14 (a), the excitation voltage U slowly rises, a current begins to flow only when the Zener voltage Uz is reached. Only at this moment does the voltage for the relay take effect according to FIG. 14 (b) RIs and capacitor C 1 existing series circuit. The condenser is charged and the relay responds. When the excitation voltage U drops according to FIG. 14 (c), the Zener diode remains ZD 4 switched through until the residual voltage Uo is reached. After falling below this residual voltage, the Zener diode ZD blocks and the flip-flop containing the transistors T 5, T 6, so that at the output of the flip-flop the voltage curve according to FIG. 14 (d) results. At this moment, the capacitor C 1 begins to discharge via the trigger stage T 2, T 3, and the relay switches in back to its original position.

FIG. 15 shows a variant of the circuit according to FIG. 2 of the patent application P 27 47 6o7.9, which consists in that in the emitter circuit of the transistor T 3, an additional pnp transistor T 11 is switched on, the base electrode of which has a reverse direction to the excitation voltage U polarized diode D 1o is connected to the positive pole of the excitation voltage. This additional measure is ensures that the semiconductor switch consisting of the transistors T 2, T 3 also occurs when higher excitation voltages occur remains reliably blocked.

In a modification of the circuit arrangement according to FIG. 1 of the patent application P 27 47 6o7.9, an npn transistor T1 'is used as a semiconductor switch according to FIG. 16, which with its emitter electrode is connected to the anode of the diode D 1 and with its base electrode to the cathode of this diode. The diode D 1 are also a Zener diode ZD 1 in the forward direction to the excitation voltage

- 6 300881/05 ^ 2

and the collector-emitter path of a switching transistor T 12 is connected upstream, and a reference voltage is applied to its base electrode lies. In the present case, the reference voltage is a series circuit made up of a resistor R 18 and another Zener diode ZD 5 implemented. The dropout voltage of the relay RIs is determined by this reference voltage.

As a variant of FIG. 16, a thyristor SCR 2 and SCR 1 is used in the circuit according to FIG. 17 instead of the npn transistors T1 'and T 12.

In the embodiment of FIG. 18 is similar to that according to Fig. 4 of the patent application P 27 47 6o7.9 for control of the semiconductor switch T 8, a Schmitt trigger with the transistors T 7, T 1o is provided. To its function also with to ensure that the excitation voltage U is switched off is in the Circuit according to FIG. 4, the storage capacitor C 3 is provided, which then takes over the power supply. In the circuit after 18 the current for operating the Schmitt trigger when the excitation voltage is switched off, on the other hand, is taken from the capacitor C. fed through a diode D 11. The arrangement according to FIG. 18 is particularly advantageous when the circuit is integrated Circuit technology is to be carried out because the storage capacitor C 3 provided in FIG. 3 is saved.

Another possibility is that the energy required for the Schmitt trigger T 7, T is available when the excitation voltage is switched off to provide is shown in FIG. 19 in that parallel to the series circuit of capacitor C 1 and relay winding RIs a pnp transistor T 15 is turned on, the base electrode of which via diodes D 11 polarized in the reverse direction to the positive pole the excitation voltage U is connected. As long as the excitation voltage is present, the diodes D are 11 and thus also the transistor T 15 blocked. When the excitation voltage is switched off, however, the transistor T 15 is conductive, so that this

3 0 '.) 8 8 1/0 5'> 2

The transistor supplies the Schmitt trigger T 7, T 1 o with its base current via the diodes D 11, which triggers the transistor switch T 8. This in turn then closes the ^ series circuit of capacitor C 1 and relay winding RIs

A further development of the circuit arrangement according to FIG. 12 is shown in FIG. 2o. As in FIG. 12, the between the base electrode of the first flip-flop transistor T 6 and the emitter electrode of the second flip-flop transistor T 5 switched on Zener diode ZD 4, that the trigger stage only becomes conductive when the Zener voltage is exceeded.

Instead of each Zener diode, it is also possible to use a parallel connection to use two diode branches, in which several diodes connected in series with the same polarity in one branch are, while in the other branch a single diode is anti-parallel. If, for example, in Fig. 2o the Zener diode ZD 1 and / or ZD 4 by such a diode parallel connection, so the dropout voltage of the relay depends on the number of those with the same polarity in a row lying diodes of a diode branch.

A further development of the circuit arrangement according to FIG. 2 of patent application P 27 47 6o7.9 is illustrated in FIG. 21, in which instead of the Zener diode ZD 1, a diode D 6 is switched on in the forward direction to the excitation voltage U. One directly Coupled multivibrator, consisting of two transistors T 13, T 14, is switched on between the terminals of the excitation voltage, the diode D 6 being between the emitter electrodes of the transistors T 13, T 14. The dropout voltage of the relay RIs becomes through the voltage divider R 19, R 2o, at whose tap the Base of transistor T 13 is determined. As long as the one you want Excitation voltage is applied to the transistor T 13

309881/0572

conductive and the transistor T 14 blocked. Excitation voltage fluctuations remain effective as long as the voltage drop occurring across resistor R 2o makes transistor T 13 conductive receives. However, if the excitation voltage drops, the control for controlling the emitter-base path of the transistor T 13 If the voltage falls below the required minimum voltage, this transistor blocks and transistor T 14 becomes conductive. Through this Measure, at a predetermined drop-out voltage, a sudden switching through of the flip-flop stage T 2, T 3 is achieved, as a result of which the capacitor C 1 is discharged and the relay RIs is switched back. Compared to Fig. 1 of the patent application P 27 47 6o7.9 a defined drop-out voltage is achieved.

The circuit according to FIG. 21 can, as FIG. 22 shows, also be modified in such a way that instead of the transistor T 14 of FIG. a diode D 7 between the collector electrodes of the transistors T 3, T 13 is switched on. Even with the circuit according to Fig. is the dropout voltage of the relay RIs by the voltage divider ratio of the resistors R 19, R 2o specified.

23 and 24 show developments of the circuit arrangement according to FIG. 3 of patent application P 27 47 6o7.9. So in Fig. in particular the diode D 1 is preceded by a further diode D 6 in the forward direction to the excitation voltage U and in the input circuit of the semiconductor switch T 2, T 3, a further diode D 9 is inserted, the cathode of which is connected to the control electrode of the semiconductor switch lies. In addition, the base electrode of the transistor T 4 is a further diode D 8 in the forward direction to Excitation voltage connected upstream as well as its collector electrode Connected via an ohmic resistor R 23 to the connection point of capacitor C 1 and semiconductor switches T 2, T 3. What is achieved by these measures is that the semiconductor switch does not inadvertently tilt at higher excitation voltages U. and an overall reduction in the current load on transistors T 2, T 3.

009881/057 '

2307673

In the two circuits according to FIG. 23 and FIG. 24, two inputs marked with + are provided, from which the upper terminal in the drawing, which is directly connected to the input of the semiconductor switch T 2, T 3, for lower excitation voltages is provided, while the lower input in the drawings as a result of the interconnection the further flip-flop stage T 5, T 6 is provided for higher excitation voltages.

The circuit arrangement of FIG. 24 differs from 23 in that instead of the further flip-flop stage T 5, T 6 a controlled by a field effect transistor FET Thyristor SCR 3 is provided. The circuit according to FIG. 1 behaves essentially in the same way as the circuit according to Fig. 23.

27 claims
Figures 5-24

300881/0572

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Claims (1)

Addition to P 27 47 6o7 »9-34 79/2/1 Claims {1 . Circuit arrangement for controlling a bistable relay, Vv 'whose excitation coil is in series with a code capacitor, in which the series connection of coil and capacitor for excitation of the relay and simultaneous charging of the capacitor is applied to excitation voltage and, in the absence of excitation voltage, through one with its output circuit to it Semiconductor switch connected in parallel can be short-circuited, whereby the relay switches back to its starting position, according to one of claims 1 to 8 of patent application P 27 47 6o7 "9-34, characterized in that the resistance element is preceded by a thyristor, to the control electrode of which a reference voltage is applied that the thyristor becomes live when the excitation voltage exceeds the level of the reference voltage « 2. Circuit arrangement according to claim 9 of patent application P 27 47 607 = 9-34, characterized in that the collector electrode of the first flip-flop transistor (pnp) (T6) with the base electrode of the second flip-flop transistor (npn) (T5) and the collector electrode of the second flip-flop transistor (T5) is connected to the base electrode of the first flip-flop transistor (T6), that the base-emitter paths of both transistors (T5, T6) are bridged with an ohmic resistor (R5, R6) each, that the base-emitter path of the second flip-flop transistor ( T5) is bridged by the parallel connection of an ohmic resistor (R 11) and a diode (D6) polarized in the forward direction to the supply voltage (U) and that between the emitter electrode of the second flip-flop transistor (T5) and the ground potential another ohmic resistor (R 12) is switched on »(Fig. 5)" 3. Circuit arrangement according to claim 9 of the patent application P 27 47 6o7.9-34, claim 1 or 2, characterized in that the reference voltage is realized by the series connection of a Zener diode (ZD2) polarized in the reverse direction to the excitation voltage and a diode (D7) with negative differential resistance, and that the flip-flop (T5, T6), or the thyristor connected upstream of the resistance element becomes live when the excitation voltage (U) exceeds the reference voltage. {Fig. 5). 4. Circuit arrangement according to claim 5 of the patent application P 27 47 6o7.9-34, characterized in that instead of the Zener diode (ZD1) connected upstream of the resistance element in the forward direction to the excitation voltage (U), a further trigger stage made up of complementary transistors (T5, T6) is provided, and that the base electrode of the first flip-flop transistor (T6) the center tap of a voltage divider (R 13, R 14) connected in parallel to the terminals of the excitation voltage (U) is connected (FIG. 7). 5. Circuit arrangement according to claim 4, characterized in that the collector electrode of the first flip-flop transistor (pnp) (T6) with the base electrode of the second flip-flop transistor (npn) (T5) and the collector electrode of the second flip-flop transistor (T5) with the base electrode of the first flip-flop transistor ( T6) is connected. (Fig. 7). 6. Circuit arrangement according to claim 4 or 5, characterized in that the divider resistor (R14) of the voltage divider connected between the base electrode of the first flip-flop transistor (T6) and the ground potential is divided into two resistors (R141, R142), that the connection point of the resistors ( R141, R142) is connected to the base electrode of a pnp transistor (T 1o), which is connected on the emitter side to one connection of the excitation voltage (U) and on the collector side with the interposition of an ohmic resistor 909831/0572 2107671 (R15) connected to the ground potential of the circuit arrangement is ,, and that the collector electrode of the transistor (T1o) is connected to the cathode of a diode (D5), the anode side at the emitter electrode of the second flip-flop transistor (T5) lies. (Fig. 8). " 7. Circuit arrangement according to claim 5 of patent application P 27 47 6o7.9-34, characterized in that the flip-flop transistor (T3) is preceded by a further transistor (npn) (T4), such that its collector electrode with the base electrode of the flip-flop transistor (T3 ), whose emitter electrode is connected to the common base of the circuit arrangement and whose base electrode is connected via an ohmic resistor (R16) to the anode of a Zener diode (ZD3) which is connected to the positive terminal of the excitation voltage (U) on the cathode side (Fig. 9), 8. Circuit arrangement according to claim 5 of the patent application P 27 47 6o7.9-34, characterized in that an ohmic resistor (R17) is switched on between the base electrode of one and the collector electrode of the other transistor of the flip-flop (T2 "T3) - (Fig- 1ο) -. 9. Circuit arrangement according to claim 5 of patent application P 27 47 6o7 "9-34, characterized in that instead of a Zener diode (ZD1) a diode (D 6) polarized in the forward direction to the excitation voltage (U) is connected upstream of the resistor element and is connected by an ohmic resistor ( R 11) is bridged. (Fig. 11). 1o. Circuit arrangement according to claim 1o of patent application P 27 47 6o7 "9-34, characterized in that to achieve the reference voltage between the base electrode of the first transistor (T 6) and the emitter electrode of the second transistor (T 5) a Zener diode (ZD 4) in the reverse direction to the exciter voltage (U) is switched on. (Fig. 12). 11. Circuit arrangement according to claim 5 of the patent application P 27 47 6o7.9-34, characterized in that an additional transistor (T 11) is switched on with its collector-emitter path in the emitter circuit of the transistor (T 3) of the semiconductor switch, and that the base electrode of the additional transistor (T 11) is connected to the positive pole of the excitation voltage via a diode (D1o) polarized in the reverse direction to the excitation voltage (U). (Fig. 15). 12. Circuit arrangement according to claim 11, characterized in that the additional transistor (T 11) is a pnp transistor »which is connected on the emitter side to the transistor (T 3) of the semiconductor switch and on the collector side to the ground potential of the circuit arrangement. 13. Circuit arrangement according to claim 2 of the patent application P 27 47 6o7.9-34, characterized in that a diode (D1) connected in the forward direction to the excitation voltage (U) is used as the resistance element and an npn transistor (T 1 ') is used as the semiconductor switch, and that the transistor (TT) is connected with its emitter electrode to the anode of the diode (D 1). (Fig. 16). 14. Circuit arrangement according to claim 13, characterized in that the diode (D 1) a Zener diode (ZD1) in the forward direction to the excitation voltage (U) and the collector-emitter path of a switching transistor (npn) (T 12) is connected upstream that between the collector elec trode of the switching transistor (T 12), which is connected to the cathode of the Zener diode (ZD 1) and an ohmic resistor (R 1) is connected to the ground potential of the circuit arrangement, and that the base 509881/05 7-2 electrode of the switching transistor (T 12) a reference voltage is created. (Fig. 16). Circuit arrangement according to Claim 14, characterized in that an ohmic resistor (R 18) is connected in series with a Zener diode (ZD 5) to generate the reference voltage. ο circuit arrangement according to claim 13 to 15 "characterized in ^ that (12 T), a thyristor, depending (SCR 1, SCR 2) was used instead of serving as a semiconductor switch npn transistor (T 1 °) and / or of the switching transistor actual (Fig- 17). 17. Circuit arrangement according to claim 15 of patent application P 27 47 6o7.9-34, characterized in that a diode (D 11) between the connection point of the capacitor C 1 with the semiconductor switch and the positive pole of the excitation voltage (U) is switched on in the reverse direction. (Fig. 18). 18. Circuit arrangement according to claim 15 of patent application 27 47 6o7.9-34, characterized in that the series connection of excitation coil (RIs) and capacitor (C) is bridged by the collector-emitter path of a transistor (pnp) (T 15), and that the base electrode of this transistor (T 15) is connected to the positive pole of the excitation voltage via at least one diode (D 11) which is switched on in the reverse direction to the excitation voltage (U). (Fig. 19). 9. Circuit arrangement according to claim 5 of patent application P 27 47 6o7 "9-34, characterized in that another made of complementary transistors is connected to the anode of the Zener diode (ZD 1) connected upstream of the resistor element 909881/0572 (T 5, T 6) built flip-flop is connected upstream, and that to the base electrode of the first flip-flop transistor (T 6) a reference voltage is applied, such that the flip-flop only becomes conductive when the excitation voltage the Exceeds the level of the reference voltage. (Fig. 2o). 20. Circuit arrangement according to claim 19, characterized in that the collector electrode of the first flip-flop transistor (pnp) (T 6) with the base electrode of the second flip-flop transistor (npn) (T 5) and the collector electrode of the second flip-flop transistor (T 5) with the base electrode of the first flip-flop transistor (T 6) is connected, that the base-emitter paths of both transistors (T 5, T 6) are bridged with an ohmic resistor (R 5, R 6) each, that between the emitter electrode lying at one terminal of the excitation voltage of the first The transistor (T 6) and the base electrode of which a capacitor (C 2) is switched on, and that a Zener diode is switched on in the reverse direction to achieve the reference voltage between the base electrode of the first flip-flop transistor (T 6) and the emitter electrode of the second flip-flop transistor (T 5). (Fig. 2o). 21. Circuit arrangement according to claim 19 or 2o, characterized in that instead of the Zener diode (ZD 1) and / or as a reference voltage source two branches of diodes connected in parallel are used that in one branch a number of diodes corresponding to the desired reference voltage in series is connected in such a way that the anode of one diode is connected to the cathode of the following diode, and in the other branch there is a single diode whose anode is connected to the cathode of the diode located at one end of the first-mentioned branch and whose cathode is connected to the anode of the am other end of the first-mentioned branch lying diode is connected. 903881/0 5 "» Ζ 22. Circuit arrangement according to claim 5 of patent application P 27 47 6o7.9-34, characterized in that instead of the Zener diode (ZD 1) a diode (D 6) is switched on in the forward direction to the excitation voltage, that a directly coupled trigger stage (T 13, T 14) between the terminals of the excitation voltage (U) is switched on, such that the diode (D 6) is between the emitter electrodes of both transistors (T 13, T 14), and that the drop-out voltage of the relay (RIs) by one for the Transistor (T 13) provided base voltage divider (R 19, R 2o) is set. (Fig. "21). 23. Circuit arrangement according to claim 5 of patent application P 27 47 6o7 "9-34, characterized in that instead of the Zener diode (ZD 1) a diode (D 6) is switched on in the forward direction to the excitation voltage, that a transistor (T 13) with a Base voltage divider (R 19, R 2o) is connected between the terminals of the excitation voltage (U) in such a way that its emitter electrode is at the anode of the diode (D 6) and its collector side with the interposition of an ohmic resistor (R 21) at the ground potential of the circuit arrangement and that another diode (D 7) is connected with its cathode to the collector electrode of the transistor (T 13) and with its anode to the collector electrode of the transistor (T 3) of the semiconductor switch. (Fig. 22). 24. Circuit arrangement according to one of claims 1 to 11 of patent application P 27 47 6o7 »9-34, characterized in that the resistor element is preceded by a diode (D 6) in the forward direction to the excitation voltage (U)» (Fig. 23). "· 8th S09331 / 05 ¹ ?! 25. Circuit arrangement according to one of claims 1 to 11 of patent application P 27 47 6o7.9-34 or claim 24, characterized in that a diode (D 9) is switched on in the input circuit of the semiconductor switch, such that its cathode is connected to the control electrode of the semiconductor switch lies. (Fig. 23). 26. Circuit arrangement according to claim 8 of the patent application P 27 47 6o7.9, claim 24 or 25, characterized in that the collector electrode of the further transistor (T 4) is connected to the connection point of capacitor (C 1) and semiconductor switch via an ohmic resistor (R 23), and that in the Base lead of the further transistor (T 4) a diode (D 8) is switched on in the forward direction to the excitation voltage (U). (Fig. 23). 27. Circuit arrangement according to claim 9, 1o of patent application P 27 47 6o7.9-34 or claim 24 to 27, characterized in that instead of the further trigger stage (T 5, T 6) a thyristor (SCR) controlled by a field effect transistor (FET) 3) is provided. (Fig. 24). 30SS81 / 057